Multiple functions for the poly(A)-binding protein in mRNA decapping and deadenylation in yeast.

Caponigro, Giordano; Parker, Roy

doi:10.1101/gad.9.19.2421

Cited by 259 publications

(266 citation statements)

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“…These data suggest that eviction of the last Pab1p molecule triggers turnover. Consistent with this view, decapping becomes independent of poly(A) in mutant strains that lack Pab1p, such that mRNAs with long poly(A) tails are decapped (Caponigro and Parker 1995). The effects of pab1 mutations on cellular mRNA levels may be complex, with contributions from turnover and/ or nuclear processes, such as mRNA 3Ј-end formation (Caponigro and Parker 1995;Amrani et al 1997;Keller and Minvielle-Sebastia 1997;Minvielle-Sebastia et al 1997;J.…”

supporting

confidence: 51%

mRNA stabilization by poly(A) binding protein is independent of poly(A) and requires translation

1998

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Translation and mRNA stability are enhanced by the presence of a poly(A) tail. In vivo, the tail interacts with a conserved polypeptide, poly(A) binding protein (Pab1p). To examine Pab1p function in vivo, we have tethered Pab1p to the 3 UTR of reporter mRNAs by fusing it to MS2 coat protein and placing MS2 binding sites in the 3 UTR of the reporter. This strategy allows us to uncouple Pab1p function from its RNA binding activity. We show that mRNAs that lack a poly(A) tail in vivo are stabilized by Pab1p, and that the portions of Pab1p required for stabilization are genetically distinct from those required for poly(A) binding. In addition, stabilization by Pab1p requires ongoing translation of the mRNA. We conclude that the primary, or sole, function of poly(A) with respect to mRNA stability is simply to bring Pab1p to the mRNA, and that mRNA stabilization is an intrinsic property of Pab1p. The approach we describe may be useful in identifying and assaying 3 UTR regulatory proteins, as it uncouples analysis of function from RNA binding.

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supporting

confidence: 51%

mRNA stabilization by poly(A) binding protein is independent of poly(A) and requires translation

1998

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“…The presence of a poly(A) tail is generally thought to be a critical determinant of mRNA stability+ For some mRNAs, poly(A) shortening or removal is the ratedetermining event in their decay, whereas, for others, it may be an obligate event in their degradation, but it is not the rate-determining step (Chen et al+, 1995;Caponigro & Parker, 1996;+ The presence of a poly(A) tail provides an mRNA with a binding site for poly(A)-binding protein, which, in turn, serves to promote translational initiation and antagonize mRNA decapping in the cytoplasm (Gallie et al+, 1989;Caponigro & Parker, 1995;Tarun & Sachs, 1996)+ In this study, the TRP4-ribozyme allele produces a transcript lacking a poly(A) tail and, as a consequence, it would be predicted that this mRNA would be susceptible to nucleolytic attack and considerably less abundant than its wild-type counterpart+ In contrast, we found that the nonpolyadenylated ribozyme transcript accumulated to levels indicative of little, if any, change in stability+ Maintenance of the stability of the poly(A)-deficient TRP4-ribozyme mRNA is likely to be a result of the action of the ribozyme in generation of the mRNA 39 end, and not to some internal TRP4 sequence features, as deletion of the TRP4 39 UTR resulted in a significant decrease in the amount of TRP4 mRNA+ In support of this idea, a previous study determined that the presence of a ribozyme in an mRNA is not sufficient to render it more labile (Donahue & Fedor, 1997)+ Several plausible explanations could account for the unchanged stability of TRP4-ribozyme mRNA+ The secondary structure formed by the hammerhead ribozyme, or the terminal 29-39cyclic phosphate (Tanner, 1999), instead of a 39-OH, might impede the accessibility of 39 exonucleases to the mRNA+ Alternatively, the absence of a poly(A) tail might uncouple an otherwise linked mechanism in which decapping is triggered by deadenylation (Muhlrad et al+, 1994)+ A more likely explanation is that degradation of the TRP4 mRNA is normally associated with its translation (Jacobson & Peltz, 1996)+ In a manner previously exemplified by the MATa1 mRNA (Parker & Jacobson, 1990), impaired translation of the TRP4-ribozyme mRNA (see below) may reduce the extent to which ribosome-associated factors act to promote decay+…”

Section: Discussionmentioning

confidence: 99%

Replacement of the yeast TRP4 3??? untranslated region by a hammerhead ribozyme results in a stable and efficiently exported mRNA that lacks a poly(A) tail

Düvel

Valerius

Mangus

et al. 2002

RNA

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The mRNA poly(A) tail serves different purposes, including the facilitation of nuclear export, mRNA stabilization, efficient translation, and, finally, specific degradation. The posttranscriptional addition of a poly(A) tail depends on sequence motifs in the 39 untranslated region (39 UTR) of the mRNA and a complex trans-acting protein machinery. In this study, we have replaced the 39 UTR of the yeast TRP4 gene with sequences encoding a hammerhead ribozyme that efficiently cleaves itself in vivo. Expression of the TRP4-ribozyme allele resulted in the accumulation of a nonpolyadenylated mRNA. Cells expressing the TRP4-ribozyme mRNA showed a reduced growth rate due to a reduction in Trp4p enzyme activity. The reduction in enzyme activity was not caused by inefficient mRNA export from the nucleus or mRNA destabilization. Rather, analyses of mRNA association with polyribosomes indicate that translation of the ribozyme-containing mRNA is impaired. This translational defect allows sufficient synthesis of Trp4p to support growth of trp4 cells, but is, nevertheless, of such magnitude as to activate the general control network of amino acid biosynthesis.

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“…Comparison of mammalian and yeast pre-mRNA 39-end-processing components reveals that, although many homologies can be found, the proteins are not function-ally interchangeable (for a recent review, see )+ An apparent case of divergence during evolution occurs with poly(A)-binding proteins+ Yeast contains a single poly(A)-binding protein (termed Pab1p), which is an essential protein present in both the nucleus and the cytoplasm (Sachs et al+, 1986)+ In the nucleus it stimulates polyadenylation and controls poly(A) tail length (Amrani et al+, 1997;MinvielleSebastia et al+, 1997;Brown & Sachs, 1998), whereas in the cytoplasm it is involved in translation initiation (Sachs & Davis, 1989;Sachs & Deardorff, 1992;Tarun & Sachs, 1995, 1996Le et al+, 1997) and mRNA degradation (Caponigro & Parker, 1995;Boeck et al+, 1998;Coller et al+, 1998)+ In contrast, mammalian cells contain two distinct proteins called poly(A)-binding protein I (PABP1) and poly(A)-binding protein II (PAB II or PABP2)+ PABP1 is predominantly detected in the cytoplasm (Görlach et al+, 1994), whereas PABP2 is localized in the nucleus (Wahle, 1991;Krause et al+, 1994)+ PABP1, which is the mammalian counterpart of yeast Pab1p (51% identity), is apparently involved in both cytoplasmic mRNA stability (Bernstein et al+, 1989;Wormington et al+, 1996;Afonina et al+, 1997;Ford et al+, 1997;Körner & Wahle, 1997) and translation (Craig et al+, 1998), but to date there is no evidence that it participates in nuclear pre-mRNA 39-end processing (see )+ Consistent with its nuclear localization, PABP2 is the mammalian protein involved in polyadenylation+ PABP2 stimulates processive poly(A) addition and controls the size of the tail to be ;250 nt in length (Wahle, 1991(Wahle, , 1995Bienroth et al+, 1993)+ How PABP2 bound to poly(A) tails in the nucleus is replaced by PABP1 in the cytoplasm remains unknown, but recent evidence indicates that both PABP1 and PABP2 shuttle between nucleus and cytoplasm (Afonina et al+, 1998;Chen et al+, 1999)+ Because it is not known when PABP1 exchanges with PABP2, one possibility is that PABP2 crosses the nuclear pores in association with the mRNA and dissoci...…”

Section: Introductionmentioning

confidence: 99%

Deciphering the cellular pathway for transport of poly(A)-binding protein II

Calado

Kutay

Kühn³

et al. 2000

RNA

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Poly(A)-binding protein II (PABP2)is an abundant nuclear protein that binds with high affinity to nascent poly(A) tails, stimulating their extension and controlling their length. In the cytoplasm, a distinct protein (PABP1) binds to poly(A) tails and participates in mRNA translation and stability. How cytoplasmic PABP1 substitutes for nuclear PABP2 is still unknown. Here we report that PABP2 shuttles back and forth between nucleus and cytoplasm by a carrier-mediated mechanism. A potential novel type of nuclear localization signal exists at the C-terminus of the protein, a domain that is highly enriched in methylated arginines. PABP2 binds directly to transportin in a RanGTP-sensitive manner, suggesting an involvement of this transport receptor in mediating import of the protein into the nucleus. Although PABP2 is small enough to diffuse passively through the nuclear pores, protein fusion experiments reveal the existence of a facilitated export pathway. Accordingly, no transport of PABP2 to the cytoplasm occurs at 4 8C. In contrast, export of PABP2 continues in the absence of transcription, indicating that transport to the cytoplasm is independent of mRNA traffic. Thus, rather than leaving the nucleus as a passive passenger of mRNAs, the data suggest that PABP2 interacts with the nuclear export machinery and may therefore contribute to mRNA transport.

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Multiple functions for the poly(A)-binding protein in mRNA decapping and deadenylation in yeast.

Cited by 259 publications

References 50 publications

mRNA stabilization by poly(A) binding protein is independent of poly(A) and requires translation

mRNA stabilization by poly(A) binding protein is independent of poly(A) and requires translation

Replacement of the yeast TRP4 3??? untranslated region by a hammerhead ribozyme results in a stable and efficiently exported mRNA that lacks a poly(A) tail

Deciphering the cellular pathway for transport of poly(A)-binding protein II

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